Silencers, silencing, and heritable transcriptional states

Although steel has been the workhorse of the automotive industry since the 1920s, the share by weight of steel and iron in an average light vehicle is now gradually decreasing, from 68.1 per cent in 1995 to 60.1 per cent in 2011 (refs 1, 2). This has been driven by the low strength-to-weight ratio (specific strength) of iron and steel, and the desire to improve such mechanical properties with other materials. Recently, high-aluminium low-density steels have been actively studied as a means of increasing the specific strength of an alloy by reducing its density. But with increasing aluminium content a problem is encountered: brittle intermetallic compounds can form in the resulting alloys, leading to poor ductility. Here we show that an FeAl-type brittle but hard intermetallic compound (B2) can be effectively used as a strengthening second phase in high-aluminium low-density steel, while alleviating its harmful effect on ductility by controlling its morphology and dispersion. The specific tensile strength and ductility of the developed steel improve on those of the lightest and strongest metallic materials known, titanium alloys. We found that alloying of nickel catalyses the precipitation of nanometre-sized B2 particles in the face-centred cubic matrix of high-aluminium low-density steel during heat treatment of cold-rolled sheet steel. Our results demonstrate how intermetallic compounds can be harnessed in the alloy design of lightweight steels for structural applications and others.

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Fe–Al–Mn–C lightweight structural alloys: a review on the microstructures and mechanical properties

Kim

Suh

Kim

2013

Science and Technology of Advanced Materials

368

124

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Adding a large amount of light elements such as aluminum to steels is not a new concept recalling that several Fe–Al–Mn–C alloys were patented in 1950s for replacement of nickel or chromium in corrosion resistance steels. However, the so-called lightweight steels or low-density steels were revisited recently, which is driven by demands from the industry where steel has served as a major structural material. Strengthening without loss of ductility has been a triumph in steel research, but lowering the density of steel by mixing with light elements will be another prospect that may support the competitiveness against emerging alternatives such as magnesium alloys. In this paper, we review recent studies on lightweight steels, emphasizing the concept of alloy design for microstructures and mechanical properties. The influence of alloying elements on the phase constituents, mechanical properties and the change of density is critically reviewed. Deformation mechanisms of various lightweight steels are discussed as well. This paper provides a reason why the success of lightweight steels is strongly dependent on scientific achievements even though alloy development is closely related to industrial applications. Finally, we summarize some of the main directions for future investigations necessary for vitalizing this field of interest.

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Atomistic Modeling of pure Mg and Mg–Al systems

Kim

Lee

2009

Calphad

125

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Thermodynamic modeling of the Mg–Si–Sn system

Jung¹,

Kang²,

Park³

et al. 2007

Calphad

129

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Transformation behavior and microstructural characteristics of acicular ferrite in linepipe steels

Kim

Lee

Kim

2008

Materials Science and Engineering: A

125

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Nack J. Kim

Brittle intermetallic compound makes ultrastrong low-density steel with large ductility

Fe–Al–Mn–C lightweight structural alloys: a review on the microstructures and mechanical properties

Atomistic Modeling of pure Mg and Mg–Al systems

Thermodynamic modeling of the Mg–Si–Sn system

Transformation behavior and microstructural characteristics of acicular ferrite in linepipe steels

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